HU222949B1 - Semi-spherical shoe - Google Patents

Abstract

BACKGROUND OF THE INVENTION The invention relates to a kinematic connection of a hemispherical sliding shoe with a hemispherical socket and a sliding plate having a planar surface which is formed by a spherical recess (1C) in the upper middle part of the hemispherical surface of the sliding shoe (1). At least one surface portion of the spherical recess (1C) of the hemispherical surface lies at an angle? = 5 ° to 65 ° to the surface of the hemispherical seat recess (2B) receiving the slip shoe (1). ŕ

Description

BACKGROUND OF THE INVENTION The present invention relates to a kinematic connection of a hemispherical slide shoe for a member having a hemispherical seat and a flat surface sliding plate, in particular for a reciprocating disk compressor.

Hemispherical slide shoes are most commonly used in reciprocating compressors between the compressor piston and the reciprocating disk for the kinematic coupling of the reciprocating piston and the reciprocating disk. One of the surfaces of the hemispherical slide shoe which fits into the hemispherical nest is typically a hemispherical backsheet which lies flat on the flat surface of the cusp.

The most common mistake of the known hemispherical slipper connection is that when the planetary disk compressor is started, the lubricating slipper gets stuck in the piston's hemispherical nozzle in the absence of lubrication.

Various solutions to overcome this error are known.

In a known embodiment, the center of the hemispherical nest has a more curved surface than the other surface portions, leaving a closed space for lubricating oil between the hemispherical surface of the slide and the surface of the nest. Alternatively, the upper, middle portion of the slipper is taped off, creating a closed space for lubricating oil above it. In a third embodiment, an axial recess is provided for the lubricating oil in the upper, central portion of the slide.

A disadvantage of the first and second known solutions is that the space for storing lubricating oil is too small. A disadvantage of the third known solution is that although an adequate volume of sealed space may be available for the temporary storage of the lubricating oil, the space is closed by closely adhering surfaces, which prevents the lubricating oil from reaching between the surfaces.

A shortcoming of the known solutions is that the lubrication of friction spherical surfaces, especially when starting, is unsatisfactory;

SUMMARY OF THE INVENTION It is an object of the present invention to overcome this shortcoming of the prior art by providing a sliding slide which aids in lubrication of the sliding contact region that provides the thrust.

The object of the present invention is to provide a hemispherical slide with a spherical recess in its upper middle part.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the following examples. In the drawing it is

Figure 1 is a cross-sectional view of a hemispherical slip joint, a

Figure 2 is a sectional view of the slide slide of Figure 1, a

Figure 3 is an enlarged detail of the slippery socket connection of Figure 1, a

Figure 4 is a schematic view of a hemispherical slipper connection, illustrating force effects,

Figure 5 is a side elevational view of another embodiment of a hemispherical slide.

1-3. Figures 1 to 5 show a first exemplary embodiment of the hemispherical slider sequence 1 of the present invention and the kinematic relationship thereto. The example relates to a kinematic relationship between a piston 2 and a piston 3 of a planetary disk compressor (element having a hemispherical seat and a flat surface sliding plate).

It is known that the planetary disk 3 fixed in an oblique (non-perpendicular) plane to the rotary axis moves the rectilinear alternating motion piston 2. At the end surface 2A of the piston 2 is a spherical slot 2B (hereinafter referred to as a hemisphere) for the slide slide 1. The recess 2B has the same arc and surface quality everywhere.

The hemispherical slide 1 has a substantially spherical (1) hemispherical upper shoe surface 1A and a substantially flat backsheet IB. The central portion of the moss surface 1A near the axis C is recessed, forming a shallow recess IC in the direction of the axis C. The backsheet IB has a conical 1D recess near its center line C. The upper IC recess is much smaller than the lower 1D recess, the upper IC recess is only one-third of the lower 1D recess.

The upper surface of the hemispherical slide slide 1A lies in the recess 2B of the piston 2 and the lower surface IB of the slide slide 1 lies on the flat surface of the planetary disk 3. The surface of the sheath 1A and the recess 2B are not fully supported on one another, with the outwardly extending gap between the surface of the recess 2B and the surface 1A extending from the transient border 1A of the piston 2 beyond the transverse border 1A.

The recess IC and the recess 2B seal a space 4, the disk 3 and a recess 1D seal a space 5 which act as a temporary lubricating oil reservoir.

As the planetary disc 3 rotates, the position (and relative angle) of the portion of its circumference on the back surface IB of the slider 1 rotates axially back and forth, thereby moving the piston 2 on the surface 1A of the hemisphere 1. Meanwhile, the backsheet IB slides on the inclined plane surface of the planetary disk 3, and the sampler surface 1A also slides in the recess 2B of the piston 2. During relative movement, oil or other lubricant stored in space 4, 5 enters between the sliding contact surfaces and provides lubrication to the friction surfaces.

In the embodiment of the present invention, illustrated in greater detail in Figure 3, the IC recess joins a smooth transition to the remainder of the Sam 1A surface and continues in a slot 8. In the IC peripheral portion between the spherical surface IC recess and the transition region 1b (Fig. 3), the wall of the IC recess lies at an angle Θ relative to the tangent of the recess 2B. The value of the angle Θ is preferably in the range of 5 ° to 30 °, but may also be in the range of 5 ° to 65 °.

The curved diameter D1 of the sliding contact area la of the sampled surface 1A differs from the curved diameter D2 of the transition region lb covering the area of the sliding contact area la of the sampled surface 1A and the recess IC.

The sliding contact area la of the sampled surface 1A is an annular (spherical) surface which is a

GB 222 949 B1 is formed near the upper IC recess, between the IC recess and the boundary 1E. The proximal recess portion IC of the shoe surface 1A, which forms a transition region 1b, and the proximal region 1E below the sliding contact area 1a of the surface 1A, does not lie on the spherical surface of the recess 2B for transmission of force.

In this embodiment, the curved diameter D2 of the shoe surface 1A in the transition region lb is larger than the diameter D1 in the sliding contact region la. This difference results in a flatter surface and thus an 8-slot opening towards the recess IC in the transition region lb between the curb surface 1A and the cavity 2B. The maximum width of the slot 8 is preferably in the range of 5 to 500 µm.

The above design results in that the lubricating oil stored in space 4 can also fill the gap 8, from where it can easily enter the slip contact area.

The non-contact region D3 of the non-contact region ld defining the sliding contact area la of the curved surface 1A from the outside of the curved diameter D1 is smaller than the curved diameter D1. In the non-contact region ld, the gap 9 extending between the shoe surface 1A and the spherical surface of the recess 2B due to the difference in curvature diameters D1, D3 is widening, beginning with the sliding contact region la. This slot 9 directs the lubricating oil which has passed through the sliding contact area la through the relative movement of the surfaces. Surfaces with curvature diameters D1, D2, D3 are not concentric, but have different centers, and pass through each other without a sudden transition.

In the sliding contact area la, the shoe surface 1A is preferably provided with a friction reducing surface which increases wear resistance. The surface layer may be MoS ₂ , Gr or other suitable synthetic resin coating. Preferably, the surface is subjected to a soft nitriding treatment prior to coating. On the other hand, the sliding contact area la of the shoe surface 1A may be coated with a hard film layer, such as an amorphous carbon (DLC) film, NI-P clad or Ni-B clad. Applying a coating may prevent tension.

1-3. 1 to 4, the back surface IB of the sliding shoe 1 of FIGS. The flat sliding contact area IF of the backsheet IB extends to its outer edge IF 'around the central ID recess, and the non-contact area 1G of the non-slip backside IB extending to the arcuate boundary 1E.

In the example, the radius of the outer edge IF 'between the sliding contact area IF and the non-contacting area 1G is less than the radial radius C from the centerline C of the sliding contact area 1A to the centerline (closer to recess IC). R distance (radius R) (Figure 2).

The height distance from the horizontal plane of the sliding contact area IF to the boundary 1E increases. By drawing an imaginary line L parallel to the axis C from the intersection of the upper edge la 'in Figure 2, the line L intersects the non-tangent region 1G of the backsheet IB at point X, which is the distance C2 at point X to the distance C1 arányítható. This ratio is preferably: C2 / Cl = <0.3. In the non-contact region 1G, the backside of the backsheet IB has a slightly convex radially curved upward curve, so that the edge of the sliding shoe 1 is higher than the upper plane of the planetary disk 3.

1-3. Figures 3 to 5 illustrate the load conditions of the sliding shoe 1 of Figs. The piston 2 responds to a sliding piston 1 supported by a piston-moving maximum load P supported by planetary discs 3 at a maximum angular position in Fig. 4, which load P is applied to the sliding contact region la and the sliding contact area IF of As can be seen from the figure, the position of the connection, including the slide 1, is well defined and stable.

During movement, the lubricant upper recess moves relative to the center of the piston surface 2B of the piston 2, thereby lubricating a portion of the piston surface 2B, upon which the sliding contact area la of the slider 1 slides. Similarly, the planetary disc 3 slides under the ID recess of the slider 1 so that the lubricant from the ID recess lubricates the flat surface of the planetary disc 3 and then slides the adjacent IF sliding contact region of the slider 1.

The center portion of the backsheet IB of the slider 1, the sliding contact region IF of the perpendicular component F of the force F and the sliding component F2 protrude better than the non-contact area 1G of the hump, so that the slider 1 is stably positioned on its plane in all angles. Good lubrication and cooling are thus ensured.

Figure 3 shows the direction of movement of the lubricating oil in the depression 2B. The lubricating oil enters the enclosure 4 above the recess IC, passing through the outer (lower) slit 9, the sliding contact area la and the inner (upper) slit 8 and discharges in the opposite direction while lubricating the sliding surfaces. This direction of flow washes the crumbs from the friction surfaces from the friction surfaces. The lubricating oil remaining in the 4 spaces and 8 slots in the first phase of the start-up provides instant lubrication to the inner surface portions.

Figure 5 shows a second embodiment of the slide 1. In this embodiment, no lower recess is formed in the backsheet IB. Otherwise, this configuration is identical to that of the sliding slide 1 of the first example, with the same advantageous properties on the shoe surface 1A.

In the examples described, it has been achieved by modifying the spherical surface of the sliding sequence 1, using different curvature diameters D1, D2 in the sliding contact area la and inlet region lb, to extend the groove IC inside the slit 9 to the inner edge la 'of the sliding contact area la. The same effect can be achieved by similar modification of the spherical surface of the 2B cavity.

The hemispherical slider of the present invention and the kinematic relationship therewith may be used primarily in planar disk compressors, but other

GB 222 949 Bl can also be used in gear units. Preferably, the spherical slot recess is formed as a sliding bearing with a insert.

The advantage of the present invention is better lubrication, less wear and warming of the tip surfaces than known.

Claims (4)

CLAIMS 1. Kinematic connection of a hemispherical sliding shoe for a member having a hemispherical socket and a sliding plate having a flat surface, characterized in that a spherical recess (IC) is formed in the upper middle part of the hemispherical surface of the sliding shoe (1). The hemispherical slipper shoe according to claim 1, characterized in that at least one surface portion of the spherical recess (IC) of its hemispherical surface lies at an angle = = 5 ° to 65 ° to the surface of the hemispherical nest recess (2B) receiving the slip shoe (1). The hemispherical slip-on shoe according to claim 1 or 2, characterized in that its backsheet (IB) is a surface embossed below the flange having a planar sliding contact region in the region around its axis (C). 10 (1F). 4. A hemispherical sliding shoe according to any one of claims 1 to 3, characterized in that the element having the hemispherical seat is a reciprocating piston (2) of a reciprocating compressor, the sliding plate is a reciprocating disc (3) of the compressor.